Title :
Asynchronous Computing in Sense Amplifier-Based Pass Transistor Logic
Author :
Liu, Tsung-Te ; Alarcón, Louis P. ; Pierson, Matthew D. ; Rabaey, Jan M.
Author_Institution :
Berkeley Wireless Res. Center, Univ. of California, Berkeley, CA, USA
fDate :
7/1/2009 12:00:00 AM
Abstract :
This paper presents the design and implementation of a low-energy asynchronous logic topology using sense amplifier-based pass transistor logic (SAPTL). The SAPTL structure can realize very low energy computation by using low-leakage pass transistor networks at low supply voltages. The introduction of asynchronous operation in SAPTL further improves energy-delay performance without a significant increase in hardware complexity. We show two different self-timed approaches: 1) the bundled data and 2) the dual-rail handshaking protocol. The proposed self-timed SAPTL architectures provide robust and efficient asynchronous computation using a glitch-free protocol to avoid possible dynamic timing hazards. Simulation and measurement results show that the self-timed SAPTL with dual-rail protocol exhibits energy-delay characteristics better than synchronous and bundled data self-timed approaches in 90-nm CMOS.
Keywords :
CMOS logic circuits; VLSI; amplifiers; asynchronous circuits; electronic engineering computing; leakage currents; timing circuits; transistor circuits; 90-nm CMOS; SAPTL; VLSI; asynchronous computing; bundled data; dual-rail handshaking protocol; energy-delay characteristics; low-energy asynchronous logic topology; low-leakage pass transistor networks; self-timing; sense amplifier-based pass transistor logic; 90-nm CMOS; Low-leakage circuits; low-voltage circuits; pass transistor; self-timing; sense amplifier-based pass transistor logic (SAPTL);
Journal_Title :
Very Large Scale Integration (VLSI) Systems, IEEE Transactions on
DOI :
10.1109/TVLSI.2008.2012054
